DE2749401A1 - Monitoring and remote control system - transmits monitoring signals as current levels converted into voltage levels for light signalling installation - Google Patents

Abstract

One single cable core is used as the signalling wire for each installation, over which monitoring signals are transmitted to a superordinate control station, and switching on/off commands from it to the light signalling installation. Monitoring signals are d.c. voltages with different levels for different signalling criteria, evaluated in the central station in a voltage level receiver allocated to a signalling installation. Monitoring signals are transmitted from the signalling installation by modulated currents whose steps correspond to signalling criteria, delivered by a stepping generator. An evaluating resistor in the central station converts the currents to corresponding voltage steps.

Description

Monitoring and remote control system for

Light signal systems The invention relates to a monitoring system and remote control system for traffic light systems according to the preamble of the patent claim 1.

In a known monitoring and remote control system of this type different defined DC voltage levels for various important feedback criteria provided, which are transmitted from the traffic lights and in a voltage stage receiver be evaluated in a control center.

Important feedback criteria are, for example, 1. The traffic light system is in operation, 2. the main direction of the intersection has green, 3. there is local manual control, 4. there is a fault Red lamp failure before, 5. there is a general malfunction of the reporting system Power failure or line interruption present.

The so-called zero voltage level is usually used for message transmission shared, for example for reporting a general fault tvgl. Return criterion 5), so that only four voltage levels are provided for five messages to be transmitted and need to be transferred. If there is a traffic hazard, the same message line transmitting the monitoring messages a switch-off command to the traffic lights in question at the intersection, which is there from a Receiver is realized.

Such voltage step systems require very precise adjustment and adaptation to the different cable networks occurring with their different ones Line resistances and voltage drops. Obstructing line resistances can mix up the voltage levels and then do readjustment work on the Sending devices of the signal systems required. Besides by environmental conditions Creeping changes in the line resistance are particularly sudden and strong Changes unpleasant. The latter changes occur in particular more common in leased lines in branched cable networks, for example telephone networks if for operational reasons - often without the knowledge of the customer - from one Cable is switched to another. Which are then already different by themselves Distance-changing voltage drops make the mentioned costs and time-consuming Re-leveling of such reporting systems is necessary.

The object of the invention is to provide a monitoring and remote control system of the type mentioned to create, in which the line resistance in certain Limits may be changeable without the need for readjustment work will.

For a monitoring and remote control system of the type specified at the beginning This object is achieved according to the characterizing part of claim 1.

By imprinting the current levels, the system becomes of the line resistance and thus largely independent of the transmission path. The transmission ranges increase enormously, transmissions over 20 km and more are now possible.

Increasing line resistances in the range of about 1 to 3 kfl from the current stage generator automatically by increasing the output voltage for so long regulated until the available maximum output voltage is reached. The self-adjustment makes constant leveling of the individual systems superfluous. The current stage generator can be used as a Plug-in card prefabricated in the factory and there, too, be adjusted. The normal voltage level receiver in the control center In addition, only one evaluation resistor has to be assigned via which the transmitted Current levels in understandable equal savings.

levels can be implemented. Conventional systems are therefore light convertible, and only one type of one is particularly cheap for storage If necessary, a receiver that can be switched to current or voltage level reception is required.

The current stage generator is advantageous as a programmable constant current source formed and consists of one of an operational amplifier over its base controlled control transistor, the emitter of which on the one hand has an inverse input of the operational amplifier is connected and on the other hand via potentiometers that can be switched on by current stage relays, can be connected to a power supply connection is.

Further essential details of the invention are set out in the claims in connection with the supplementary drawing and explanatory description.

The invention is illustrated by means of a schematic exemplary embodiment explained in more detail below: The figure shows the basic circuit structure a current stage generator, which is housed on a circuit board I (dash-dotted) is. The circuit board I is useful designed as a plug-in card. The current stage generator consists of a programmable constant current source from a C, eration amplifier -1 (e.g. of the type TAA 762) and a control transistor 2 built. The transmitted current levels go from the output connection A of the circuit board 1 via a message line 3 (dashed) with a symbolically indicated line resistor RL to a receiver unit a in a control center 11.

The transmitted direct current levels are in the range between to 20 mA and are separated from each other by approx. 4 mA.

The receiver unit a consists of an evaluation resistor 4 and a modified voltage stage receiver known per se 5. The power supply the circuit board I takes place via connections B and C, where connection B is connected to +100 V. lies wr.d Terminal C leads to zero potential. Connection D leads to a ground return conductor 6 of the center II, the several similar ones. Receiver units a, b, c for signal systems different crossing gene is common. The message lines 3, 3 ', 3' 'are individual each assigned to separate circuit boards I, as is only detailed here for the receiving unit a. Groups of up to 10 plants can be can be connected to a common ground return conductor 6, for example. Means Potentiometer that can be looped into the output circuit (emitter-collector path) of the control transistor 2 7,8,9,10 are fed via a voltage drop feedback to the control transistor 2 influencing operational amplifier 1 set the desired current level. The potentiometers 7 to 10 can range from contacts Ila to 14a Associated current stage relay 11 to 14 in the output circuit of the control transistor 2 can be looped in. Certain current stage relays 11 or 12 or 13 or 14 are always respond to monitoring devices not shown here Control unit, which is located, for example, with circuit board I at the intersection, Switch according to the reporting criteria already mentioned. Symbolically to be evaluated Changeover contacts of a green signaling element (17) of a local relay with manual actuation (18) and a red monitor (19) are shown. The associated connections the circuit board I are labeled E to H. At the connection K there is a common one Power supply. The further reference symbols are taken from the following functional description emerged.

When the signal system is switched on, the central unit 1 should be ready for operation reported back to the system. At the connections K and E of the circuit board I. voltage will normally be present when the control unit is switched on, and the current stage relay 11 will tighten. The contact 11 a will close and the potentiometer 7 in the Loop in the emitter line of the control transistor 2. The operational amplifier 1 and the control transistor 2 are then connected to voltage via the potentiometer 7. Of the voltage level at the inverse input (pin 4) of operational amplifier 1 in relation to the voltage levels of the given by the reference diodes 15 and 16 Entrances 2, 3 and 6 causes a positive at the output of the operational amplifier 1 (pin 7) Base current for the control transistor 2, which controls this on. About the set Potentiometer 7 is a defined negative collector current of the control transistor 2 preselected, in the present case the lowest current level 1 with e.g. approx. 8 mA. This current is iLer the message line 3 to the evaluation resistor 4 of the receiver unit a impressed, set in a corresponding voltage level and a voltage level receiver 5 understood as the feedback "signal system in operational readiness". The voltage drop on the potentiometer 7 by the flowing working current influences the emitter on the one hand of the control transistor 2 and, on the other hand, the inverting input (F.n 4) of the operational amplifier 1 in such a way that an equilibrium is established. Every change in the terminating resistor, for example by increasing the standard line resistance the message line 3, influences the voltage drop on the ootentiometer via the current 7 so that the set equilibrium is disturbed. For example, increases the external resistance, so causes the reduced current and thus voltage drop on potentiometer 7 through the feedback to the inverting input (pin 4) of the operational amplifier 1 a positive increase in the output voltage at pin 7 of the amplifier and thus a further control of the control transistor 2. The The set current level is thus up to the complete control of the control transistor 2 automatically kept constant. Only when the control transistor is fully controlled 2 the control limit is reached, it is then practically the full one Operating voltage at the output.

The Zener diode 20, which acts as a voltage threshold, breaks down.

and lets the light-emitting diode 21 light up. This makes it clear that the line or terminating resistance has become too high.

In connection with zero voltage reception in the control center, there is also a line break recognizable.

When the signal system is operating properly, every time the main direction is green, the switch 17 of the green feedback is the one on the left Take position and use the current step relay 12 with contact 12a to adjust the potentiometer 6 grind in. The subordinate current stage relay; 1 for the potentiometer 7 on the other hand falls away. This sets a higher current level 2, which - as before - is sent via message line 3 to control center 2. Again, the Current level kept exactly constant and, as described, the terminating resistor is monitored. In proper operation, the changeover contact 17 is constantly switching and the Receiving unit a of the control center II a constant oscillation between the current levels 1 and 2.

If the signal system is controlled by hand independently of the control center, then a further increased via changeover contact 18 and ultimately potentiometer 9 Current level 3 switched on, which is activated for central unit 2 by a permanent signal (the There is no need to change current levels 1 and 2) an unusual situation can be identified power. Red monitoring has the highest priority. Is there one here? If there is a fault, the red monitor will operate the switch 19 and via the current stage relay 14 program the highest current level 4 with the potentiometer 10.

Everything below is switched off. This message can be sent by the central If initiate a switch-off command. For each shutdown command, the changeover switch 22 is actuated and a positive switching signal from a voltage source 29 (here +60 V) via the message line 3 to the circuit board I. This is for Evaluation equipped with a bran E. receiver III (framed by dash-dotted lines), which can be reached by the positive switching signal via a decoupling diode 23. An optocoupler becomes an optocoupler via current limiting elements 24, 25, 26 and a light-emitting diode 27 28 applied to its output amplifier a switch-off command via the outputs L, Y. passes on to circuit breakers not shown. These switch the Plant off. If a positive switch-off signal is given by the control center II, then this can be seen by the lighting up of the diode 27.

Regarding the receiver units a, b in the control center II it should be noted that that each consists of an evaluation resistor 4 or 4 'or

4 '', which shows the incoming constant current stages in constant voltage level converts, and a downstream modifiable voltage stage receiver 5 or 5 'or 5' '. The one in every normal voltage level receiver when receiving voltage levels otherwise existing constant current source, which ensures that at every voltage level to Keeping the voltage drop constant via RL the same current flows is used for Current level reception of the receiver unit switched off a or b or c. So can im the simplest case by simply changing a switching bridge from voltage level reception can be modified to receive current levels. The obtained voltage level impedance converted four different to a common one adjustable reference voltage source connected threshold value elements, as sensors of the individual current or voltage levels.

The operating state is determined via the relevant threshold value element detected by the signaling system.

The invention not only increases the transmission range. with a higher immunity to interference, in particular a significant simplification given in maintenance.

The circuit board 1 also provides absolute galvanic separation between the cable network and the control unit.

8 claims 10 pages description 1 sheet. Drawings L. e e r e i t e

Claims (8)

P a t e n t a n s p r ü c h e: 1. Monitoring and remote control system for light signaling systems with only one cable aden as a signaling line per system, Via the monitoring messages to a higher-level control device or central unit or switch-on / switch-off commands can be transmitted from this to the light signal system and the monitoring messages as DC voltages for various reporting criteria different level in a voltage level receiver assigned to the traffic signal system can be evaluated in the control device or central unit, characterized in that that the transmission of the monitoring messages from the traffic light system by means of impressed current levels assigned to the reporting criteria are carried out by a Stromstufeger.erato @ preferably located in the control unit of the system and in the higher-level control device or control center (II) by means of a Evaluate ~ resistance (4) in for the voltage stage receiver (5) understandable DC voltage levels can be implemented. 2. Monitoring and remote control system according to claim 1, characterized in that that the current stage generator is designed as a programmable constant current source is and from one controlled by an operational amplifier (?) via its base Control transistor (2) consists, the emitter of which on the one hand has an inverse input (Pin 4) of the operational amplifier (1) is connected and on the other hand via potentiometer (7 to 10), which can be switched on by current stage relays (11 to n4): d 'a power supply connection (C) connectable @@ t. 3. Monitoring and remote control system according to claim 1 or 2, characterized characterized, dan the current stage relays (11 to 14) by switching devices (17 to 9) can be controlled by monitoring devices of the traffic light system (Connections E to K). 4. Monitoring and remote control system according to claims 1 to 3, characterized in that the current stage generator with the associated current stage relay is housed on a circuit board (I). 5. monitoring and remote control system according to claims 1 to 4, characterized in that each circuit board (1) a switch-off receiver (III), the collector path of the control transistor (2) between this and the output connection (A) to the message line (3) via a diode (23) from the current stages is connected decoupled. 6. ¢ monitoring and remote control system according to claim 5, characterized in that that the decoupling diode (23) for positive DC voltage signals from the Zer.traleinheit (a) is passable and via an optocoupler (28) of the switch-off receiver (III) isolated switch-off commands can be triggered (connections L, M). 7. Monitoring and remote control system according to one of the preceding Claims, characterized in that the full activation of the control transistor (2) is indicated by a light-emitting diode (21) on the circuit board (1), which is between the potentials of the signal line (3) and the ground conductor (6) is connected. 8. Monitoring and remote control system according to claims 4 and 5, characterized in that the optocoupler (28) is controlled by a DC voltage signal the central unit (a) from a series-connected light-emitting diode to the optocoupler (28) is displayed.